DE19643619B4 - Apparatus and method for receiving a sheet from a first direction and for feeding the sheet in a second direction - Google Patents

Abstract

Apparatus for receiving a sheet (20) from a first direction (A) and for transporting the sheet (20) in a wide direction (B) that is not parallel to the first direction (A), the apparatus comprising:
- means (260, 270, 280) for feeding the sheet (20) in the second direction (B);
- A deck (110, 150) having an input end (102) for receiving the sheet (20) from the first direction (A) and an output end (104), wherein the deck, a lower cover plate (110) and a vertically in comprising a top cover plate (150) disposed above the bottom deck, the top cover plate (150) being pivotally mounted for rotation between a closed position where the bottom cover plate (110) and the top cover plate (150) are substantially parallel , and an open position in which the distance between input ends of the lower cover plate (110) and the upper cover plate (150) is greater than that of the ...

Description

The This invention relates generally to foliar processing machines. Especially This invention is directed to an apparatus and method for receiving or for receiving a sheet from a first direction and the Respectively of the leaf in a second direction.

Out DE 90 00 255 U1 a guide device for printers is known, which serves for pressing a print carrier to a print carrier support. Each vane assembly associated with a idler roll is connected thereto so as to be raised and lowered together with the idler roll in response to the thickness of the print carrier. As a result, not only the guide gap provided between the guide roller and the print carrier support but also the distance between the guide surface arrangement and the print carrier support are adapted to the print carrier thickness. The print carrier is guided by the direction, reciprocated while a printhead is moved vertically.

Insertion systems that can produce over 10,000 mail pieces per hour are well known in the art. Generally, inserter systems are used by organizations such as banks, insurance companies, and commodity companies to generate a large volume of specific mailings, with the contents of each mail item addressed to a particular addressee. In addition, other organizations, such as direct mailers, use inserters to generate a large volume of generic mailings in which the contents of each mailpiece are substantially identical for each addressee or recipient. Examples of such inserter systems are the 8 Series ^™ and 9 Series ^™ inserter systems disclosed by Pitney Bowes, Inc. Stamford, CT. are available.

In In many ways, a typical inserter system is similar to a production line. Bows or other raw materials (other bows, plants, envelopes) occur as inputs to the inserter system one. Then work a variety of different modules or Workstations in the inserter system together to the bows to work until a final mailpiece will be produced. The exact configuration of each inserter system depends on the needs of each customer or installation from. Thus, the typical inserter system includes modules such as the following: Various tissue treatment modules (slitting devices, cutting devices and Burster) to the continuous forms of a tissue into individual or separate leaves to separate a summary or accumulator module to summarize the leaves in a collation (sorting), a folding module for folding sorting into a desired one Configuration (Z-folding, C-folding, half-folding), a transport / grading module, to transport sorting and queuing, a variety of plant feeder modules to assemble and add a package of attachments to the sort, an insert station module to insert the Sorting into an envelope, and a synchronization control system the operation of the entire inserter system, to ensure that the sorts are assembled in an appropriate way.

It Facilities are known that sort or sheets inside to turn a plane. These facilities are often used in inserter systems used to change the orientation of the leaves (for example, from the Landscape on the portrait view and vice versa), so one further downstream To facilitate processing. Another application for reversing devices exists in the mixing of leaves of a first series of leaves in a second series of leaves. Examples of inverters used in inserter systems are in U.S. patents with the following numbers: 4,909,374 A, 5,180,154 A, 5,180,159 A, 5,188,355 A and 5,413,326 A. These are all assigned to the assignee of the present invention Service. Such devices are usually referred to as a rectangular transport device (RAT).

The RAT receives a leaf from one upstream located module and delivers the sheet to a downstream Module. Typically, the RAT comprises a first feeder for feeding the Sheet in a first direction, a second feeding means for feeding the Leaf in a second direction and a reorientation facility. The reorientation facility is turning the tide from the first one Direction new in the second direction by pulling the sheet from the first Supply means to the second feed device is transferred. Although these conventional RATs are generally good work, their production is costly and they prove lots of space. Therefore, they are not suitable for all applications.

Accordingly, there is a need for an apparatus and method for receiving a sheet from a first direction and feeding the sheet in a second direction without using a feeder in the first direction so as to reduce cost and size. In addition, the device and Ver drive single sheets, small books, a variety of folded sheets or other sheet configurations can handle without operator settings, so as to reduce operating costs and construction time.

The The present invention provides an apparatus and a method for Receiving a sheet from a first direction and feeding the sheet in a second direction, where the two directions are not parallel to each other. Conventionally, this invention used to make a leaf from a landscape view to reorient a portrait view or vice versa.

According to the present In the invention, the device comprises the features described in claim 1 are indicated. Advantageous embodiments will be apparent from the dependent claims 2 to 5.

According to the present Invention, the method comprises the steps in the claim 6 are indicated. Advantageous embodiments emerge the dependent claims 7 to 10.

The accompanying drawings incorporated in part of the description are, and form part of, constitute a presently preferred embodiment of the invention, and together with the general above and the detailed description given below Description of the preferred embodiment for explanation the principles of the invention. As shown everywhere in the drawings, like reference numerals designate like or corresponding parts. In the figures show:

1 a plan view of an apparatus for receiving a sheet from a first direction and for transporting the sheet in a second direction, according to the present invention;

2 a cross-sectional view along an in 1 shown section line 2-2;

3 a cross-sectional view along an in 1 shown section line 3-3; and

4 a block diagram of the device according to the present invention.

With reference to 1 is a device 100 with an input end 102 for receiving or receiving a sheet 20 from a first direction, as indicated by the arrow "A", and an output end 104 for transporting the sheet 20 in a second direction as indicated by the arrow "B". Generally, the sheet becomes 20 from an upstream module (not shown) from the first direction into the device 100 fed in and from the device 100 in the second direction to a downstream module (not shown). Here, the term sheet means: a single sheet, a plurality of sheets, a small book, a folded plurality of sheets, or another type of sort configuration.

With reference to the 1 to 3 includes the device 100 a lower cover plate 110 , an upper cover plate 150 , a sensor 210 , a pair of stops (stoppers) 216 , a pivoting construction 220 and a transport structure 260 that are aligned to successive sheets or sheets 20 to feed in the second direction. The lower cover plate 110 is fixedly attached to any suitable framework of a conventional device, while the upper cover plate 150 pivotable on the lower cover plate 110 is appropriate. The space between the lower cover plate 110 and the upper cover plate 150 defines a paper path. In the preferred embodiment, the lower cover plate 110 and the upper cover plate 150 Made of a sheet metal (sheet metal). However, other suitable materials may be used therefor.

The bottom plate 110 includes a variety of approaches or cones 112 while the top cover plate 150 a variety of flanges 152 includes. The cones 112 and flanges 152 are formed by sections of the cover plates 110 respectively. 150 are bent upwards. waves 190 are through the holes in the pins 112 and flanges 152 pushed to the top cover plate 150 on the lower cover plate 110 pivotally mount. The waves 190 can be secured by any suitable means, for example by an E-clamp (not shown). Additionally, bearings can be used in the holes to increase the stability of the top cover plate 150 increase and provide a smoother rotation with less friction. As a result, the upper cover plate is 150 free to move between an open position and a closed position around the waves 190 to turn. Gravity tends to the upper cover plate 150 to hold in the closed position and spacers 196 that are on the lower cover plate 110 Keep a suitable distance between the lower cover plate 110 and the upper cover plate 150 upright. Thus, in the closed position, the cover plates are substantially parallel. It is important to point out that the spacers 196 located outside of the paper path, leaving the leaves 20 do not interfere when they enter the device 100 enter, and leave.

The pivoting structure 220 turn on Lektiv the upper cover plate 150 from the closed position to the open position. It includes a rotary solenoid 222 firmly attached to the underside of the lower cover plate 110 from an L-shaped carrier 224 is appropriate. An end of the arm 226 is fixed to the actuator of the solenoid 222 attached, so that the arm 226 together with the actuator turns when the solenoid 222 is energized. At the other end of the arm 226 is rotatable a roll 228 appropriate. The solenoid 222 , the arm 226 and the role 228 are arranged so that when the solenoid 220 is turned off, and the upper cover plate 150 located in the closed position, the role 228 just the bottom of the lower cover plate 110 touched. When the solenoid 222 is energized, the arm turns 220 in a clockwise direction, like out 3 visible, and pivots the upper cover plate 150 in the open position, as shown with dashed lines.

The sensor 210 is a conventional optical sensor of the reflective type and includes a light emitter and a light detector for measuring the amount of reflected light. The sensor 210 is on the lower cover plate 110 placed and positioned so that it directs a beam of light in the paper path, so the existence of the leaves 20 capture. If a sheet 20 is present, light is reflected back to the detector. On the other hand, if there is no sheet, no light is reflected back to the detector. Thus, by monitoring the amount of light received by the detector, a determination can be made as to whether the sheet 20 exists or not. So that the upper cover plate 150 does not reflect the light back to the detector when a sheet 20 is absent, thus causing the detector to provide an incorrect measurement, includes the top cover plate 150 a section 156 , the light from the device 100 lets emerge. Therefore, the detector receives more light when a sheet 20 exists, in contrast to the case where a leaf 20 not available.

The attacks 216 keep a movement of the leaves 20 in the first direction and are slidable at slots 114 in the lower cover plate 110 appropriate. That's why the attacks are 216 adjustable to leaves 20 different size. So that an operator has access to the attacks 216 has to get them along the slots 114 reposition, contains the upper cover plate 150 cutouts 158 , The attacks 216 may be of any suitable construction, for example a typical spring biased bolt and nut arrangement.

After the attacks 216 the movement of the leaves 20 have stopped in the first direction, leads the transport structure 260 the leaves 20 continue in the second direction. The transport structure 260 includes a sliding finger transport structure 270 and a take-away transport construction 320 , The sliding finger transport construction 270 includes a pair of endless belts or straps 272 that are about respective sets of slices 274 . 276 and 278 extend around. The bands or straps 272 run below the lower cover plate 110 and include sliding fingers (transport pins) 280 extending over the lower cover plate 110 lift and fall under these, just like the straps 272 rotate. To the sliding fingers (transport pins) 280 not obstructing, contains the lower cover plate 110 cutouts 116 while the top cover plate 150 cutouts 160 contains. As in 2 As can be seen, the bands rotate 272 in the clockwise direction.

The removal transport construction 320 includes an endless belt 322 That's about the slices 324 and 326 and normal power or pressure rollers 328 and 330 extends. The endless band 322 extends over the lower cover plate 110 through a section 118 , The disks 276 and 324 use a wave together 250 while the slices 278 and 326 a common wave 252 share. The remaining discs and rollers are correspondingly on shafts 254 . 256 and 258 held. The waves 250 . 252 . 254 . 256 and 258 are rotatably mounted on any suitable structure (not shown) in a conventional manner. The wave 252 is operatively coupled to a drive system (not shown) around the shaft 252 to cause it to rotate and thus the required input drive for the sliding finger transport structure 320 and the removal transport construction 320 supply. Because the disc 326 a larger diameter than the discs 278 has, is the transport speed of the removal structure 320 larger than that of the sliding finger assembly 270 ,

With reference to 4 is a tax system 400 shown which with the sensor 210 , the solenoid 222 and the transport structure 260 communicates. The tax system 400 may be any suitable combination of hardware and software to perform its function of controlling the operation of the device 100 to reach. The sensor 210 puts on the control system 400 an indication of the existence or absence of leaves 20 ready. Based on the status of the sensor 210 turns on the control system 400 the solenoid 222 selectively. In addition, the control system controls 400 the operation of the transport structure 260 ,

With the main structural aspects of the present invention described above, the operational characteristics of the present invention will be described below with reference to FIGS 1 - 4 described. To one leaf 20 from the upstream module (not shown), which moves in the first direction as indicated by the arrow "A", switches the control system 400 the solenoid 222 a, so the upper cover plate 150 to pivot in the open position. In the open position, the input end is the upper cover plate 150 further from the corresponding input end of the lower cover plate 110 spaced as this is the case when the top cover plate 150 is in the closed position. That's why the sheet can 20 easier to enter the paper path without a jam. To prevent the sheet from entering the device 100 to support, includes the lower cover plate 110 and the upper cover plate 150 suitable insertion flanges 120 respectively. 162 at their input ends. In addition, another advantage is achieved when the lower cover plate 110 slightly below the output level of the upstream module.

Because the upper cover plate 150 is in the open position and there is nothing in the paper path to the sheet 20 to hinder, a moment causes the leaf 20 to continue a movement in the first direction. The cutouts 116 . 160 and 156 include all suitable flanges (not shown), so as to avoid the risk of congestion when the sheet 20 along the paper path between the lower cover plate 116 and the upper cover plate 150 moved in the first direction. As soon as the sensor 210 the leading edge of the sheet 20 detected, the control system turns off 400 the solenoid 222 off to the top cover plate 150 attributed to the closed position. At this time the tide has changed 20 far inside the device 100 emotional. The leaf 20 runs continuously in the first direction until it hits the stops 216 impinges, which prevent any further movement in the first direction. If the sheet 20 on the attacks 216 its speed has been considerably reduced due to friction. Therefore, the probability of jumping back is minimal. However, a brush (not shown) or other means could be added to prevent excessive springback.

As soon as the sensor 210 the leading edge of the sheet 20 captured, the control system waits 400 a predetermined amount of time before it the transport pins 280 advanced. This guarantees that the sheet 20 the attacks 216 has reached and is ready for transport in the second direction. The control system controls the feed of the transport pins 280 in a conventional manner, so that the transport pins in an appropriate timed sequence with the arrival of the sheet 20 work. It is important that the transport pins 280 not in the paper path when the sheet moves in the first direction. When the transport pins 280 over the lower cover plate 110 Lift, contact the sheet 20 and lead the sheet 20 in the second direction on the take-off construction 320 out. If the leading edge of the sheet 20 in the gap between the roll 328 and the band 322 enters, sets the sheet 20 feeding in the second direction, but at a reduced speed. Therefore the removal construction has 320 a control over the sheet 20 taken over and moved the sheet in front of the transport pins 280 forward, before the transport pins under the lower cover plate 110 fall. The removal construction 320 puts a feeder of the sheet 20 from the device 100 out and toward the downstream module (not shown).

At any time before the arrival of a subsequent sheet 20 turns on the control system 400 the solenoid 222 Finally, what causes the top cover plate 150 is pivoted in the open position. The timing of when this exactly occurs is a matter of design choice. However, the upper cover plate should be 150 stay in the closed position, at least until the sheet 20 into the gap of the removal construction 320 so as to have proper control over the sheet 20 maintain.

It should now be apparent that the device 100 provides a rectangular transport device without having a feeder in the first direction. That's why the device uses 100 the moment or the momentum that the leaf 20 from the upstream module. This reduces the cost of the present invention unlike other systems.

It should also be apparent that the pivoting top cover plate 150 provides the benefit of being able to handle single sheets, small books (a large number of sheets), and another configuration without the need for operator set up. If the sheet 20 Made up of a single sheet, then it moves easily between the cover plates until it stops 216 reached. However, if the sheet 20 is made of a large number of sheets, this would usually not occur due to friction. In this case, the friction on the leaves 20 thereby reducing that the upper cover plate 150 is placed in the open position because the leaves 20 on the upper cover plate 150 Do not rub until it returns to the closed position. This ensures that the leaves 20 have sufficient moment to stop 216 to reach. On the other hand, if the upper cover plate 150 would be set in the closed position, then a large number of leaves or a heavy accumulation of leaves could be the stops 216 do not reach and one Misalignment or a jam would likely occur.

Another advantage is that the pivoting upper cover plate 150 a clamping effect on the folded leaves 20 downwards, without undesirable entrainment or friction on the folded leaves 20 to create. Those persons who are familiar with the technique will see that folded leaves 20 need to be controlled so that they do not jump back (expand) and unfold. Extended folded leaves often cause jams and it is difficult to keep them properly aligned. Therefore, the upper cover plate stops 150 in the closed position, leaves folded from jumping back too far without exerting excessive drag on the leaves.

Those skilled in the art will appreciate that the present invention allows a large number of sheets or a plurality of folded sheets to enter the apparatus from a first direction without causing excessive drag on the sheets by making a swiveling top plate 150 having. Once the leaves have essentially completed their movement in the first direction, then the upper cover plate 150 returned to the closed position, leaving the leaves 20 be suitably controlled, and ready for feeding in the second direction.

Many features of the preferred embodiments represent design choices that are chosen to best exploit the inventive concept as implemented to produce a ninety-degree directional change. However, with minor modifications, the present invention can be designed to achieve directional changes at different angles. In addition, the structural components of the present invention have many known substitutions. For example, the upper cover plate 150 on any other structural element than the lower cover plate 110 be attached. As another example, the sensor 210 be replaced by a mechanical switch. However, this is because of the leaves 20 not preferred.

Most importantly, those who are familiar with the technique will find many substitutions for the pivot construction 220 already obvious. For example, the rotary solenoid can be replaced by a linear (push-pull) solenoid with only minor changes. In this embodiment, the arm would operate as a see-through with a centrally located fixed pivot, the roller being rotatably mounted on one end of the arm and the other end of the arm pivotally attached to the linear solenoid. Another example is a cam mechanism. Again, in this embodiment, the arm behaves as a viewer with a centrally located fixed pivot, the roller being rotatably mounted on one end of the arm. However, at the other end of the arm, a follower roller would be rotatably mounted and biased by a spring so that the follower roller remains in contact with a cam. Those familiar with the technique will easily find other substitutes.

There many modifications of the present invention to those persons easily familiar with the art, is the invention in its broader aspects, not to the specific details the preferred embodiment limited. As a result, can Various modifications are made without departing from the spirit deviate from the general inventive concept, as it is from the attached claims and their equivalents is defined.

Claims (10)

Device for receiving a sheet ( 20 ) from a first direction (A) and for transporting the sheet ( 20 ) in a wide direction (B) that is not parallel to the first direction (A), the device comprising: - means ( 260 . 270 . 280 ) for feeding the sheet ( 20 ) in the second direction (B); - a deck ( 110 . 150 ), which has an input end ( 102 ) for receiving the sheet ( 20 ) from the first direction (A) and an output end ( 104 ), wherein the deck has a lower cover plate ( 110 ) and a vertically at a distance above the lower deck arranged upper cover plate ( 150 ), the upper cover plate ( 150 ) is pivotally mounted, for rotation between a closed position, at which the lower cover plate ( 110 ) and the upper cover plate ( 150 ) are substantially parallel, and an open position in which the distance between input ends of the lower cover plate ( 110 ) and the upper cover plate ( 150 ) is greater than that of the closed position; - An institution ( 220 ) for pivoting the upper cover plate ( 150 ) between the closed position and the open position, - a control device ( 400 ) in operative connection with the pivoting device ( 220 ) to: the pivoting device ( 220 ), the upper cover plate ( 150 ) to pivot in the open position to the sheet ( 20 ) from the first direction (A) to the pivoting device ( 220 ), the upper one Cover plate ( 150 ) in the closed position upon receipt of the sheet ( 20 ) and about the feeder ( 260 . 270 . 280 ) to cause the sheet ( 20 ) through the deck issue end ( 104 ) in the second direction (B). Device according to claim 1, characterized in that the sheet ( 20 ) moves along a paper path from the input end to the discharge end of the deck, and further comprising one with the control device ( 400 ) in operative connection sensor device ( 210 ), which is located along the paper path, for detecting the presence of the sheet, and wherein the control device ( 400 ) the pivoting device ( 220 ), the upper cover plate ( 150 ) from the upper position to the lower position after the sensor device ( 210 ) detects the leaf. Device according to claim 1 or 2, characterized in that the control device ( 400 ) the feeding device ( 260 . 270 . 280 ) causes the sheet ( 20 ) in the second direction through the deck output end after the sensor device ( 210 ) detects the leaf. Device according to claim 1, 2 or 3, further comprising a stopping device ( 216 ), which is located along the paper path, to stop a movement of the sheet ( 20 ) in the first direction (A), and wherein the feeding device ( 260 . 270 . 280 ) feeds the sheet in the second direction (B) after the sheet has stopped moving in the first direction (A). Device according to one of claims 1 to 4, characterized in that the pivoting device ( 220 ) comprises: - a rotary solenoid ( 222 ) firmly attached to the lower plate ( 110 ) is attached; - one arm ( 226 ) having a first end and a second end fixedly attached to the rotary solenoid ( 222 ) are mounted to rotate when the solenoid is energized; and - a role ( 228 ) rotatable at the first end of the arm ( 226 ), the control system controlling the rotary solenoid ( 222 ), what the role ( 228 ), against the upper cover plate ( 150 ) and the upper cover plate ( 150 ) to pivot on the closed position to the open position. A method of receiving a sheet from a first direction (A) and transporting the sheet in a second direction (B) that is non-parallel to the first direction (A), the sheet ( 20 ) moves along a paper path through a deck ( 110 . 150 ) with an input end ( 102 ) and with a lower cover plate ( 110 ) and an upper cover plate ( 150 ) vertically spaced from the lower cover plate (FIG. 110 ) and is pivotally mounted to move between a closed position in which the lower cover plate ( 110 ) and the upper cover plate ( 150 ) are substantially parallel, and an open position in which the distance between input ends of the lower cover plate ( 110 ) and the upper cover plate ( 150 ) is greater than that of the closed position, the method comprising the steps of: (a) pivoting the top cover plate (11) 150 ) from the closed position to the open position; (b) receiving the sheet ( 20 ) from the first direction (A) into the input end ( 102 into it; (c) pivoting the upper cover plate ( 150 ) from the open position to the closed position; and (d) after step (c), feeding the sheet ( 20 ) in the second direction (B). The method of claim 6, further comprising the steps of: (e) detecting the presence of the sheet ( 20 ) along the paper path, and then performing step (c). The method of claim 7, further comprising the step of: (f) stopping a movement of the sheet ( 20 ) in the first direction (A) before the execution of step (d). Method according to claim 8, characterized in that that step (a) occurs before step (b) and step (e) occurs before step (f). Method according to one of claims 6 to 9, characterized in that the step (a) further comprises the following step: (g) switching on a rotary solenoid ( 222 ), which firmly attached to the lower cover plate ( 110 ), so that a roll ( 228 ) rotatable at a first end of an arm ( 226 ) fixedly attached to a second end of the rotary solenoid ( 222 ) is attached to the upper cover plate ( 150 ) and the upper cover plate ( 150 ) pivoted from the closed position to the open position.